Innovative insights into extrachromosomal circular DNAs in gynecologic tumors and reproduction

Originating but free from chromosomal DNA,extrachromosomal circular DNAs(eccDNAs)are organized in circular form and have long been found in unicellular and multicellular eukaryotes.Their biogenesis and function are poorly understood as they are characterized by sequence homology with linear DNA,for which few detection methods are available.Recent advances in high-throughput sequencing technologies have revealed that eccDNAs play crucial roles in tumor formation,evolution,and drug resistance as well as aging,genomic diversity,and other biological processes,bringing it back to the research hotspot.Several mechanisms of eccDNA formation have been proposed,including the breakage-fusion-bridge(BFB)and translocation-deletion-amplification models.Gynecologic tumors and disorders of embryonic and fetal development are major threats to human reproductive health.The roles of eccDNAs in these pathological processes have been partially elucidated since the first discovery of eccDNA in pig sperm and the double minutes in ovarian cancer ascites.The present review summarized the research history,biogenesis,and currently available detection and analytical methods for eccDNAs and clarified their functions in gynecologic tumors and reproduction.We also proposed the application of eccDNAs as drug targets and liquid biopsy markers for prenatal diagnosis and the early detection,prognosis,and treatment of gynecologic tumors.This review lays theoretical foundations for future investigations into the complex regulatory networks of eccDNAs in vital physiological and pathological processes.

The effect of pore size on the mechanical properties, biodegradation and osteogenic effects of additively manufactured magnesium scaffolds after high temperature oxidation: An in vitro and in vivo study

The effects of pore size in additively manufactured biodegradable porous magnesium on the mechanical properties and biodegradation of the scaffolds as well as new bone formation have rarely been reported. In this work, we found that high temperature oxidation improves the corrosion resistance of magnesium scaffold. And the effects of pore size on the mechanical characteristics and biodegradation of scaffolds, as well as new bone formation, were investigated using magnesium scaffolds with three different pore sizes, namely, 500, 800, and 1400 μm (P500, P800, and P1400). We discovered that the mechanical characteristics of the P500 group were much better than those of the other two groups. In vitro and in vivo investigations showed that WE43 magnesium alloy scaffolds supported the survival of mesenchymal stem cells and did not cause any local toxicity. Due to their larger specific surface area, the scaffolds in the P500 group released more magnesium ions within reasonable range and improved the osteogenic differentiation of bone mesenchymal stem cells compared with the other two scaffolds. In a rabbit femoral condyle defect model, the P500 group demonstrated unique performance in promoting new bone formation, indicating its great potential for use in bone defect regeneration therapy.

Functional analysis of the methyltransferase SMYD in the single-cell model organism Tetrahymena thermophila

Lysine methylation of histones and non-histones plays a pivotal role in diverse cellular processes.The SMYD(SET and MYND domain)family methyltransferases can methylate various histone and non-histone substrates in mammalian systems,implicated in HSP90 methylation,myofilament organization,cancer inhibition,and gene transcription regulation.To resolve controversies concerning SMYD's substrates and functions,we studied SMYD1(TTHERM_00578660),the only homologue of SMYD in the unicellular eukaryote Tetrahymena thermophila.We epitope-tagged SMYD1,and analyzed its localization and interactome.We also characterized △SMYD1 cells,focusing on the replication and transcription phenotype.Our results show that:(1)SMYD1 is present in both cytoplasm and transcriptionally active macronucleus and shuttles between cytoplasm and macronucleus,suggesting its potential association with both histone and non-histone substrates;(2)SMYD1 is involved in DNA replication and regulates transcription of metabolism-related genes;(3)HSP90 is a potential substrate for SMYD1 and it may regulate target selection of HSP90,leading to pleiotropic effects in both the cytoplasm and the nucleus.

MBRidge: an accurate and cost-effective method for profiling DNA methylome at single-base resolution

Organisms and cells,in response to environmental influences or during development,undergo considerable changes in DNA methylation on a genome-wide scale,which are linked to a variety of biological processes.Using MethylC-seq to decipher DNA methylome at single-base resolution is prohibitively costly.In this study,we develop a novel approach,named MBRidge,to detect the methylation levels of repertoire CpGs,by innovatively introducing C-hydroxylmethylated adapters and bisulfate treatment into the MeDIP-seq protocol and employing ridge regression in data analysis.A systematic evaluation of DNA methylome in a human ovarian cell line T29 showed that MBRidge achieved high correlation(R>0.90)with much less cost(∼10%)in comparison with MethylC-seq.We further applied MBRidge to profiling DNA methylome in T29H,an oncogenic counterpart of T29’s.By comparing methylomes of T29H and T29,we identified 131790 differential methylation regions(DMRs),which are mainly enriched in carcinogenesis-related pathways.These are substantially different from7567 DMRs that were obtained by RRBS and related with cell development or differentiation.The integrated analysis ofDMRsin the promoterand expression of DMR-corresponding genes revealed thatDNAmethylation enforced reverse regulation of gene expression,depending on the distance fromthe proximalDMRto transcription starting sites in both mRNA and lncRNA.Taken together,our results demonstrate that MBRidge is an efficient and cost-effective method that can be widely applied to profiling DNA methylomes.

Identification and analysis of intermediate-size noncoding RNAs in the rhesus macaque fetal brain

Although only about 2%of the human genome has proved to be protein-coding genes,recent advances in genome wide analysis have revealed that the majority of the genome is transcribed,mainly from noncoding segments that were once considered＂junk sequences＂or＂dark matters＂（Liu et al.,2011a;Zhang et al.,2014b）. In addition to the well-characterized housekeeping non- coding RNAs （ncRNAs） （tRNA, rRNA, small nuclear RNA and small nucleolar RNAs） and some small regulatory ncRNAs （microRNAs and small interfering RNAs）, the transcriptome of mammals could also pervasively have been transcribed long noncoding RNAs （lncRNAs, at least 200 nt） （Rinn and Chang, 2012; Xie et al., 2012）.